Logic Modeling for NSDI Implementation Plan
A Case Study in Indonesia
Tandang Yuliadi Dwi Putra and Ryosuke Shibasaki
Civil Engineering Department, University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo, Japan
Keywords: National Spatial Data Infrastructure (NSDI), Logic Model, Strategic, Implementation.
Abstract: The importance of sharing and reusing geographic information for national development programs has led
many countries establishing National Spatial Data Infrastructures (NSDIs). Indonesia is one of the early
adopters of NSDI which begun the initiative in the 1990’s. Some achievements have been made; nevertheless,
there are also constraints of NSDI implementation identified by the stakeholders. Considering recent
improvement in geospatial technology that has changed the landscape of NSDI into more user-driven location
services, NSDI coordinator needs to compose a comprehensive framework that integrates requirements and
detailed activities as the realization of strategies. This paper presents a strategic planning using logic model,
incorporating components of the NSDI in Indonesia including policy, institutional arrangements, technology,
standards and human resource issues. A logic model visualizes systematic programs and connecting related
activities with the projected outcomes. The model started with the identification of requirements through in-
depth interviews and documents study to provide insight for NSDI implementation. Subsequently, it
determines intended impact and outcomes, analyses activities, defines expected outputs from NSDI initiative
and identify the resources for the operation. Our proposed model can be useful for the implementation of
NSDI particularly for countries that do not have strategic management yet or are considering improving it.
1 INTRODUCTION
Realizing benefits of sharing and reusing geographic
information for supporting national development
programs has led many countries establishing
National Spatial Data Infrastructures (NSDIs) for the
past 25 years. Basically, NSDI is a framework of
technology, standards, policy and collaboration of
different institutions to provide access, exchange and
utilization of spatial data at the national level
(Rajabifard et al., 2003). From the initial aims to
reduce data duplication and improve access to
geospatial data, NSDI applications nowadays have
played significant role in the decision making process.
Examples can be found in the area of cadastral
services (Borzacchiello and Craglia, 2013), disaster
risk management (Molina and Bayarri, 2011) and
urban planning (Poorazizi et al., 2015).
Despite of its potential benefit in supporting
national development programs, scholars have found
that NSDI implementation has several obstacles.
Crompvoets and Bregt (2007) and Van Oort et al.
(2009) identify a declining trend of national geoportal
key product of an NSDI due to the fact its
functionalities do not meet the expectations of the
geospatial community. In addition, although NSDI
initiatives mostly originated from the government
agency, not all of decision makers share the same
awareness. This lead to the lack of cooperation and
sharing information with other institutions (Janne &
Lorkhamyong, 2015). Another problem is related to
the insufficient funding for the implementation and
maintenance of an NSDI (Ayanlade et al., 2008).
The difficulties recognized above shows that
successful implementation of an NSDI depends on
not only from technical aspect but also financial and
institutional efforts. NSDI development also involves
dynamic negotiations and arrangements between
different actors, which considered as the complexity
of SDI initiatives (De Man, 2006). Therefore, in order
to overcome these problems NSDI coordinator
requires a comprehensive framework for its
implementation that incorporates requirements and
detailed activities as the realization of strategies. This
paper presents a strategic planning using logic models
for each component of NSDI including policy,
institutional arrangements, technology, standard and
human resource issues, with a case study in Indonesia.
Yuliadi Dwi Putra, T. and Shibasaki, R.
Logic Modeling for NSDI Implementation Plan.
DOI: 10.5220/0006755502470254
In Proceedings of the 4th International Conference on Geographical Information Systems Theor y, Applications and Management (GISTAM 2018), pages 247-254
ISBN: 978-989-758-294-3
Copyright
c
2019 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
247
The paper starts with an overview of NSDI
development in Indonesia and describes
chronological milestones that have been achieved. A
brief literature review of the logic models then
presented in the next section. Subsequently, the
proposed methodology to develop program logic
models for NSDI implementation is explained.
2 NSDI IMPLEMENTATION IN
INDONESIA
Indonesia was considered as one of the eleven
countries who adopt the first generation of NSDI
(Masser, 1999). The NSDI development was initiated
in 1991 by a first group meeting called SIGNas
(Sistem Informasi Geografis Nasional/National
Geographic Information System) Forum among
different government agencies with the agenda to
identify the availability of Geographic Information
System (GIS) data and avoid data duplication
(Lilywati and Gularso, 2000). The National
Coordinating Agency for Surveying and Mapping
(Bakosurtanal) organized the meeting and continued
in the next few years by discussing various related
topics. One of them is the introduction of National
Geodatabase, which was discussed in the third
meeting in 1997 (Matindas et al., 2004).
The formal declaration of NSDI was defined in
the National Coordination Meeting of Survey and
Mapping in 2000 with the term “Infrastruktur Data
Spasial Nasional” (IDSN). The objective is to provide
good quality, easily accessed and integrated spatial
data for national development (Bakosurtanal, 2008).
Since then, efforts and activities to develop NSDI
have been conducted. The milestones of NSDI
development in Indonesia described in term of legal,
organizational aspect and technical issue is presented
in Figure 1.
Enactment of the Geospatial Information Law in
2011 is the main foundation of NSDI development in
Indonesia. One of the law’s goals is to ensure the
availability of, and access to, accountable geospatial
information. In order to achieve this, geospatial
information infrastructure needs to be established
which incorporates five pillars: policy, institutional
arrangements, technology, standards, and human
resources. With the enactment of this law,
Bakosurtanal was also transformed into Badan
Informasi Geospasial (BIG) as the national agency
organizing geospatial information. As part of the
application of Geospatial Information Law, the
Indonesian government initiated the ‘One Map Policy’
in 2015 and publish a presidential decree on the next
year to accelerate its implementation. One Map
Policy aims to tackle overlapping thematic maps
among institutions so there shall only one base map
to be used as reference by other government agencies
(Tim Percepatan Kebijakan Satu Peta, 2017).
In the organizational aspect, NSDI Secretariat was
established two years after the declaration as a
working body to plan and manage all NSDI meetings,
agreements, and recommendations (Matindas et al.,
2004). The members are representatives from
government institutions, and universities. To date, the
secretariat is chaired by the Deputy of Geospatial
Information Infrastructure from BIG.
Institutional arrangement of Indonesia NSDI is
defined by the Presidential Decree No. 27/2014,
which replaced the previous one issued in 2007, about
the National Geospatial Information Network.
Figure 1: Chronological milestones of NSDI development in Indonesia.
GISTAM 2018 - 4th International Conference on Geographical Information Systems Theory, Applications and Management
248
According to the decree, the actors for geospatial
information sharing are called network nodes (Simpul
Jaringan), which are classified into central and local
network nodes. Central network nodes include
ministries and national government agencies while
local network nodes consist of provincial, municipal,
and district governments. Each node has
responsibility in the collection, maintenance, update,
exchange and dissemination of specific geospatial
data. These nodes have their own clearinghouse unit
and should connect to the national geoportal.
After the year 2000, the implementation of NSDI
has undergone some changes in the technical aspects.
A Clearinghouse, typical evidence of the first
generation of SDI, was developed in 2004 as a
continuation of metadata development. Federal
Geographic Data Committee (FGDC) standard was
adopted and metadata servers were connected in a
distributed network to display information about the
digital maps (Puntodewo and Nataprawira, 2007).
The national geoportal, namely Ina-Geoportal
(http://tanahair.indonesia.go.id), was launched in
October 2011. The portal facilitates geospatial data
access and sharing between government institutions.
It utilizes web services – the main technological
indicator of the second SDI generation – to retrieve
maps provided by data providers and re-use it to
create thematic data services. Data center was also
settled since 2013 to support the operational of Ina-
Geoportal (BIG, 2014). Moreover, the increase use of
smartphones has triggered the development of mobile
version of Ina-Geoportal in 2015 (BIG, 2015a).
In term of standards, the Geospatial Information
Law defines standards for five aspects of geospatial
information: geospatial data acquisition, information
processing, storage and security, information
distribution, and information usage. These standards
can be in the form of national standards (Standar
Nasional Indonesia/SNI) or technical specifications.
BIG has initiated the development of national
standards since 2000 and had already produced 60
SNI (BIG, 2015b). BIG also developing technical
specification, which stipulated by a decree of the head
of BIG. For example, Indonesian Geospatial
Reference System description named SRGI2013.
Advancement of spatial technology and the
Internet have changed the landscape of NSDI. Harvey
et al. (2012) argued that future NSDI will be
influenced by the growing use of mobile computing
and crowdsourcing, thus lead to the need to integrate
various types of data. This means that the aims of an
NSDI may not only for sharing and integrating data
from static sources but also producing new
information and allowing a user to interact
dynamically with the data providers. Consequently,
NSDI implementation in Indonesia should consider
such condition and an inclusive strategic management
is required for its effective functioning.
3 LOGIC MODEL REVIEW
3.1 Definition of Logic Model
Logic model is one of the methods that can be used in
developing design, plan, and evaluation of a project.
It presents a systematic and visual way of the
connections between resources, planned activities
and its expected results (W. K. Kellogg Foundation,
2004). Logic model offers the strategic means to
critically review and improve project’s
implementation. Additionally, logic model can
illustrate parts of or whole systems and clarify
complex relationships among them.
3.2 Benefits
Knowlton and Phillips (2013) identify several
benefits of using logic models as follows:
Develop common understanding among
stakeholders;
Document and emphasize explicit outcomes;
Recognize important variables for the
evaluation purpose.
3.3 Types and Components of Logic
Model
Logic model can be distinguished into two types:
theory of change and program (Knowlton and Phillips,
2013). The difference between them is on the level of
detail and use, although both represent the same logic.
A theory of change logic model presents
conceptual view of how the project will “do and get”.
It simply displays the big picture of the project using
limited information. A basic theory of change logic
model consists of two elements: strategies and results
as illustrated in Figure 2. Strategies reflect a choice of
optimal actions to achieve intended results.
Figure 2: Theory of change model (Adopted from
Knowlton and Phillips, 2013).
Logic Modeling for NSDI Implementation Plan
249
Figure 3: A basic program logic model (Adopted from W. K. Kellogg Foundation, 2004).
A program logic model describes a more detailed
map of the project from start to finish. Strategies are
broken down into resources, activities, and outputs
whereas results reflect the sequence of outcomes over
time through impact. It displays the elements that are
most critical in establishing and operating a project.
Key components of a program logic model is
presented in Figure 3 and explained as follows:
Resources or inputs are something that available
or needed to conduct activities. They can include
financial, human, or organizational aspect.
Activities specify the particular actions that will be
delivered as project implementation. Generally, they
are related to deliberate events, tools, process or
technology.
Outputs are the direct products of project
activities. They are usually quantified and described
in targets, level of functioning or type of services to
be achieved by the project.
Outcomes define what kind of changes expected
to happen as a result of the project. Some examples
are specific changes in awareness, knowledge or
behavior. Outcomes may be divided based on time
periods into short, intermediate, and long term.
Impact is the ultimate change arising in
organization, community or system. Sometimes it
reflects the intended project’s vision or goal.
The rational of logic models follows “if-then”
statements, which connect all parts of the project.
From left to right it can be read, “If we have the
following resources, then we can deliver these
activities. If we accomplish the planned activities,
then we can produce intended outputs. If we have
these outputs, then certain changes will be happened
in organization or community,” and so on.
The purpose of this study is to provide
comprehensive strategic directions and action plans
for NSDI coordinator, hence a program logic model
is used.
4 DEVELOPING NSDI LOGIC
MODEL
4.1 Problems and Requirements
Identification
The practical development of a program logic model
generally starts with one or more information
discovery process such as interviews, observations or
documents study (Knowlton and Phillips, 2013).
NSDI stakeholders’ point of view is necessary to be
captured for understanding more about its current
implementation. Stakeholders might influence the
effective functioning of NSDI or affected by it. This
research identifies problems of NSDI implementation
and requirements of future NSDI from the
perspectives of government institutions, private
sectors, and academia.
Semi-structured interviews were conducted in
June and August 2017 for data collection. The
familiarity of the authors with the NSDI initiative in
Indonesia helped them to find appropriate individuals
that have experience, knowledge, and role in its
implementation. Overall, there were 18 participants
of the interviews, in which eight of them represents
government agencies, seven are working at private
companies, and the rest are from academic
institutions. They included SDI coordinators at
ministries and local governments, a key technical
NSDI manager, a representative from data providers,
a director of GIS department, a web mapping solution
provider, and an SDI research coordinator. The three
main questions asked to them are “What are the
problems and challenges of NSDI implementation?”,
“What kind of data and services should be provided
by NSDI?”, and “How is your expectation for future
NSDI?”.
A wide variety of problems occurred in NSDI
implementation were mentioned in our interviews.
The most frequent answer is the lack of human
resources that have capability in GIS field. This
shortfall is recognized mainly by government
institutions where employee rotation often occurs.
The number of staff who have ability to manage
geospatial information and operate geospatial server
to publish map services is also limited. The second
major problem is low participation of the NSDI
GISTAM 2018 - 4th International Conference on Geographical Information Systems Theory, Applications and Management
250
network nodes, thus resulting a small number of
datasets accessible in Ina-Geoportal. According to the
interviewee, low participation may caused by the lack
of awareness of NSDI benefits or there is a reluctance
to share geospatial data. Other difficulties identified
by the respondents are include large-scale dataset
availability, geoportal Issue, financial aspect and
Information and Communication Technology (ICT)
infrastructure. Table 1 summarizes the problems
stated by interviewees from Public (Pu), Private (Pr)
and Academic (Ac) institutions, together with the
number of times they were stated.
Table 1: Problems of NSDI implementation and the number
of times stated by different type of institutions.
Problems of NSDI
Type of Institutions
Sum
Pu Pr Ac
Lack of skilled human
resources
5 3 2 10
Low participation from
the NSDI network nodes
3 1 1 5
Insufficient large-scale
maps
1 1 2 4
Limited functionality
and reliability of the
Ina-Geoportal
1 2 1 4
Low spatial data quality 1 2 1 4
Limited Internet and
ICT infrastructure
2 2 - 4
Absence of operational
guidance
1 2 - 3
Limited funding 1 1 - 2
Low adoption of GIS
technology
1 1 - 2
Lack of standards
implementation
- 2 - 2
Most interviewees stated that they require large-
scale fundamental datasets to be provided by NSDI.
Its availability will be important as the base map to
generate other thematic datasets such as urban
planning and public utility management. Meanwhile,
the majority of respondents from business sector need
socio-economic data that represents population
distribution and other commercial information.
Although the data can be obtained at Central Bureau
of Statistics, it will be more useful if the data is in the
form of geospatial services and can be integrated with
other applications. Some of the respondents also
considered Real-time data from weather or
environmental sensors is essential particularly to
support early warning system. Other data or service
requirements for future NSDI implementation are
presented in the Table 2.
Table 2: Data/services required by different type of
institutions and the number of times stated.
Required data/services
Type of Institutions
Sum
Pu Pr Ac
Large-scale fundamental
datasets
6 2 1 9
Socio-economic data - 4 - 4
Real-time weather and
environment data
2 1 1 4
Point of Interest (POI) data - 2 1 3
Disaster risk information 1 1 1 3
Land parcels 1 - 1 2
Spatial planning 1 1 - 2
Different expectations of future NSDI were
expressed by the interviewees. In general, they expect
to have more geospatial data and applications. They
believe NSDI should be able to provide good quality
spatial data in term of resolution and completeness as
the basis for added-value information creation. Some
of the respondents consider future application of
NSDI will be integrated with different types of data
to support geospatial analytics, which is important for
Table 3: Expectations of future NSDI from users’ point of
view.
Type of
Institutions
Expectation
Local
government
NSDI can handle and integrate in situ
data which is collected by sensor
networks
NSDI should encourage creation of
location-based mobile applications
NSDI should support the provision of
geospatial data
National
government
Access to high-resolution spatial data will
be more easy and reliable
Integrate various thematic maps and data
formats produced by network nodes
The development of NSDI should be
sustainable, not a partial project
Private
sector
NSDI should provide geo-services
applications for general user and
developer
Improve the quality and reliability of
geospatial data
Future NSDI should drive the
development of geospatial industry in
Indonesia
Academia
NSDI should increase data coverage and
geo-services in remote area
NSDI should promote value-added
creation of geospatial data that stimulate
innovation
NSDI will increase the awareness of
decision makers
Logic Modeling for NSDI Implementation Plan
251
decision makers. Table 3 presents the detailed
expectations of future NSDI categorized by type of
institutions.
4.2 NSDI Logic Model
The identification of problems and requirements from
previous section gives significant insight for NSDI
implementation. Together with other evidences
collected from formal documents such as regulations,
annual reports, and BIG’s strategic plan, they are used
as key information sources of the NSDI logic model.
The creation of NSDI logic model begins by
determining the intended ultimate goal. Based on the
declaration of Indonesia NSDI in 2000, its objective
is to deliver good quality, easily accessed and
integrated spatial data to support national
development (Bakosurtanal, 2008). However, based
on the expectation of users, future NSDI should not
limited to only support governmental development
programs but also accessible to citizens and
businesses. They expect geospatial information
commonly available and can be consumed by handy
applications to fulfill their needs. This also complies
with one of the purposes of Geospatial Information
Law, which is to encourage geospatial information
usage in various aspects of community life. Therefore,
the proposed final impact is to achieve geospatially
enable society, a term introduced by Steudler and
Rajabifard (2012) to describe the desired condition.
The next step is to define outcomes of NSDI
implementation. We parsed the expected outcomes by
time increments into short, intermediate, and long
term. Short-term outcomes are planned to be realized
in 1 through 3 years, intermediate-term outcomes 4
through 6 years, and long-term outcomes in 7 through
10 years.
Short-term outcomes are related to changes in the
aspect of geospatial data quality, awareness of the
NSDI benefits, and knowledge of geospatial
information. The geospatial data quality here is also
including the completeness and coverage of the large-
scale maps that urgently required by stakeholders. If
data quality can be improved then the intermediate-
term outcome expected is the decision-making
process will be better. Additionally, increased
awareness will result in better participation from
network nodes and partnerships among stakeholders,
as well as increased knowledge produce improved
skill and technology adoption. If we accomplish these
three intermediate outcomes, then the change in
national development and geospatial industry
hopefully will be secured in the long term.
Subsequently, we have to identify all the activities
required to generate the outcomes. There are six main
strategies proposed: mapping activities, One Map
implementation, improving data access and sharing,
promoting geospatial community, capacity building
activities, and developing NSDI practices. Each of
these strategies will produce outputs that
collaboratively resulted in the model’s outcomes.
The purpose of mapping activities is to produce
large-scale topographic maps that most users required.
These basic maps then are used as the foundation of
developing thematic maps produced by a variety of
institutions. With One Map implementation,
problems in overlapping land status for instance, can
be tackled and the integrated thematic maps will
increase the quality of geospatial products. Moreover,
research outputs from the capacity building activities
may also support the improvement in terms of
accuracy of the products.
An enhanced geoportal platform is the main
output of improving data access and sharing activities.
It is expected to have more functionalities and support
marketplace for the private sector to stimulate
innovation. We also believe participation from group
of users that sharing similar interest in geospatial
information is need to be raised. Activities to promote
geospatial communities should be determined in
order to encourage them creating Location Based
Service (LBS) applications and participating in
adding Point of Interest (POI) database. This
initiative will require support from business sector
and academia. If the geoportal is running well and
provide useful applications, then the awareness of
geospatial information benefits will be increased for
decision-makers and general users as well.
Capacity building activities can be related with
the human, technological, and institutional aspects.
As discovered in the previous subsection, it is
important to overcome insufficient skilled human
resources in GIS field. BIG has established
collaboration with 13 universities as the Center of
Spatial Data Infrastructure Development (Pusat
Pengembangan Infrastruktur Data Spasial/PPIDS)
(BIG, 2015a). However, the partnership should be
strengthened to produce not only qualified personnel
but also conduct valuable research in geospatial
information area. In addition, formulation of
competency standards are also required to guarantee
the quality of the workforce.
One of the problems identified in NSDI
implementation is the absence of operational
guidance. Local governments expect that best
practices of NSDI in terms of technical and
institutional issues are available. For example,
GISTAM 2018 - 4th International Conference on Geographical Information Systems Theory, Applications and Management
252
Figure 4: NSDI Logic Model.
practical guideline is needed in setting up a
clearinghouse and data sharing management with
other agencies. NSDI Practices activities aims to
provide such documents and assistance in order to
increase the knowledge of NSDI stakeholders.
The final step is to determine resources for the
effective NSDI operation. We distinguished seven
inputs including geospatial data, policy, funds,
institutional arrangements, technological facility,
standards, and human resources. In case of Indonesia,
most of them are already available because the NSDI
initiative has been started more than two decades ago.
For example, the basic policy for NSDI is described
in the Geospatial Information Law and further
arranged by government regulation or presidential
decree. Nevertheless, some efforts need to be
expanded particularly for geospatial data and funding.
The complete NSDI logic model is presented in
Figure 4. It visualize relationships between elements
in the road map from the planned strategies to the
intended results. This model can also promote
alignment and synergy in conducting activities
among NSDI stakeholders.
4.3 Detailed Activities and Outputs
The NSDI Logic Model describes an overview of the
strategic directions for NSDI implementation.
Nonetheless, it can be breakdown to provide a more
detailed view of the activities and intended outputs.
In Figure 5, we show the detail within the mapping
strategy. It consists of five key activities: GCP
measurement, Ortho-image processing, develop
Positioning Infrastructure, Geodatabase updating and
LIDAR processing. The target is to produce numerous
large-scale topographic maps which important for
generating thematic maps. Each activity has a
quantified output to be delivered. For example, number
of Ground Control Points (GCP) is the objective of the
GCP measurement that required for making ortho-
rectified satellite images. This closer picture of
operations can be helpful in creating the action plans.
Figure 5: Detailed mapping activities and their outputs.
Logic Modeling for NSDI Implementation Plan
253
5 CONCLUDING REMARKS
Indonesia has underway an evolution in developing
NSDI. Several milestones in term of legal settings,
institutional arrangements, standardization and
technological issues have been delivered. However, it
is evident from stakeholders’ perspective that
problems still occur particularly in providing skilled
workforces and abundant large-scale maps. Trends of
latest geospatial technology and users demand has
changed the NSDI ultimate goal into geospatial
information usage in various aspects of the general
public life. To realize this geospatially enabled
society, we propose the NSDI Logic Model as a
comprehensive and visible strategic direction.
Our work contributes to providing a scientific
management tool for implementing effective NSDI.
With this model, well-planned actions and their
expected results can be generated as well as
communicating a common understanding to NSDI
stakeholders. Future works will be to validate this
model with key players and determine outcome-based
indicators for the successful of NSDI implementation.
ACKNOWLEDGEMENTS
This research was supported by the Program for
Research and Innovation in Science and Technology
Project (RISET-Pro).
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